Dual arm movement control by a neurobotics model

Author

Khemaissia, Seddik

Author_Institution

Electron. Technol. Dept., Riyadh Coll. of Technol., Saudi Arabia

Volume

3

fYear

2001

fDate

2001

Firstpage

2086

Abstract

One of the amazing successes of biological systems is the ability of animals to learn to control the complicated dynamics of their muscles and joints smoothly and efficiently. Traditional engineering control techniques, on the other hand, often do not perform well when confronted with intrinsically complex systems with many degrees of freedom such as a robot arm (human arm). This paper presents new work on compliant motion control. Based on previous physiological information, the authors propose an intelligent adaptive system based on a decentralised motor learning model of the cerebellum. The resultant neuro-adaptive model is used as a hybrid force/position controller for a dual arm. To optimise the neural network learning strategy, a hybrid neuro-genetic algorithm is introduced and simulation results are given for comparisons

Keywords

control system analysis; control system synthesis; decentralised control; force control; genetic algorithms; learning (artificial intelligence); motion control; neurocontrollers; optimal control; position control; robots; cerebellum; compliant motion control; control simulation; decentralised motor learning model; dual arm movement control; hybrid force/position controller; hybrid neuro-genetic algorithm; intelligent adaptive system; neural network learning strategy; neuro-adaptive model; neurobotics model; physiological information; Animals; Biological control systems; Biological system modeling; Biological systems; Brain modeling; Control systems; Force control; Humans; Muscles; Robots;

fLanguage

English

Publisher

ieee

Conference_Titel

Industrial Electronics Society, 2001. IECON '01. The 27th Annual Conference of the IEEE

Conference_Location

Denver, CO

Print_ISBN

0-7803-7108-9

Type

conf

DOI

10.1109/IECON.2001.975614

Filename

975614